Block cipher

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The basic function of block ciphers is to keep messages or stored data secret; the intent is that an unauthorised person be completely unable to read the enciphered material. Block ciphers therefore use a key and are designed to be hard to read without that key. Of course an attacker's intent is exactly the opposite; he wants to read the material without authorisation, and often without the key. See cryptanalysis for his methods.

These standards greatly influenced the design of other block ciphers, and the latter part of this article is divided into sections based on that. DES and alternatives describes 20th century block ciphers, all with the 64-bit block size of DES. The AES generation describes the next generation, the first 21st century ciphers, all with the 128-bit block size of AES. Large-block ciphers covers a few special cases that do not fit in the other sections.

Context

Block ciphers are essential components in many security systems. However, just having a good block cipher does not give you security, much as just having good tires does not give you transportation. It may not even help; good tires are of little use if you need a boat. Even in systems where block ciphers are needed, they are never the whole story. This section gives an overview of the rest of the story; it aims to provide a context for the rest of the article by mentioning some issues that, while outside the study of the ciphers themselves, are crucially important in understanding and using these ciphers.

Any cipher is worthless without a good key. Keys must be kept secure, they should be large enough and sufficiently random that searching for the key (a brute force attack) is effectively impossible, and in any application which encrypts large volumes of data, the key must be changed from time to time. See the cryptography article for discussion.

It is hard to design any system that must withstand adversaries; see cryptography is difficult. In particular, block ciphers must withstand cryptanalysis; it is impossible to design a good block cipher, or to evaluate the security of one, without a thorough understanding of the available attack methods. Also, Kerckhoffs' Principle applies to block ciphers; no cipher can be considered secure unless it can resist an attacker who knows all its details except the key in use. Analysis of security claims cannot even begin until all internal details of a cipher are published, so anyone making security claims without publishing those details will be either ignored or mocked by most experts.

A block cipher defines how a single block is encrypted; a mode of operation defines how multiple block encryptions are combined to achieve some larger goal. Using a mode that is inappropriate for the application at hand may lead to insecurity, even if the cipher itself is secure. A block cipher can be used to build another cryptographic function such as a random number generator, a stream cipher, or a cryptographic hash. These are primarily a matter of choosing the correct mode, but there are more general design issues as well; see the linked articles for details.

Block ciphers are often used as components in hybrid cryptosystems; these combine public key (asymmetric) cryptography with secret key (symmetric) techniques such as block ciphers or stream ciphers. Typically, the symmetric cipher is the workhorse that encrypts large amounts of data; the public key mechanism manages keys for the symmetric cipher and provides authentication. Generally other components such as cryptographic hashes and a cryptographically strong random number generator are required as well. Such a system can only be as strong as its weakest link, and it may not even be that strong. Using secure components including good block ciphers is certainly necessary, but just having good components does not guarantee that the system will be secure. See hybrid cryptosystem for how the components fit together, and information security for broader issues.

That said, we turn to the block ciphers themselves.

Size parameters

One could say there are only three things to worry about in designing a block cipher:

make the block size large enough that an enemy cannot create a code book, collecting so many known plaintext/ciphertext pairs that the cipher is broken.

make the key size large enough that he cannot use a brute force attack, trying all possible keys

then design the cipher well enough that no other attack is effective

Getting adequate block size and key size is the easy part; just choose large enough numbers. This section describes how those choices are made. Making ciphers that resist attacks that are cleverer than brute force (see cryptanalysis) is far more difficult. The following section, Principles and techniques covers ideas and methods for that.

If two or more ciphers use the same block and key sizes, they are effectively interchangeable. One can replace another in almost any application without requiring any other change to the application. This might be done to comply with a particular government's standards, to replace a cipher against which some new attack had been discovered, to provide efficiency in a particular environment, or simply to suit a preference.

Nearly all cryptographic libraries give a developer a choice of components, and some protocols such as IPsec allow a network administrator to select ciphers. This may be a good idea if all the available ciphers are strong, but if some are weak it just gives the developer or administrator, neither of whom is likely to be an expert on ciphers, an opportunity to get it wrong. There is an argument that supporting multiple ciphers is an unnecessary complication. On the other hand, being able to change ciphers easily if one is broken provides a valuable safety mechanism. Striking some sort of balance with a few strong ciphers is probably the best policy.

Block size

The block size of a cipher is chosen partly for implementation convenience; using a multiple of 32 bits makes software implementations simpler. However, it must also be large enough to guard against code book attacks.

DES and the generation of ciphers that followed it all used a 64-bit block size. To weaken such a cipher significantly the attacker must build up a code book with 232 blocks, 32 gigabytes of data, all encrypted with the same key, As long as the cipher user changes keys reasonably often, a code book attack is not a threat. Procedures and protocols for block cipher usage therefore always include a re-keying policy.

However, with Moore's Law making larger code books more practical, NIST chose to play it safe in their AES specifications; they used a 128-bit block size. This was a somewhat controversial innovation at the time (1998), since it meant changes to a number of applications and it was not absolutely clear that the larger size was necessary. However, it has since become common practice; later ciphers such as Camellia, SEED and ARIA also use 128 bits.

There are also a few ciphers which either support variable block size or have a large fixed block size. See the section on large-block ciphers for details.

Key size

In theory, any cipher except a one-time pad can be broken by a brute force attack; the enemy just has to try keys until he finds the right one. However, the attack is practical only if the cipher's key size is inadequate. If the key uses <math>n</math> bits, there are 2n possible keys and on average the attacker must test half of them, so the average cost of the attack is 2n-1 encryptions.

Current block ciphers all use at least 128-bit keys, which makes brute force attacks utterly impractical. Suppose an attacker has a billion processors in a monster parallel machine (several orders of magnitude more than any current machine) and each processor can test a billion keys a second (also a generous estimate; if the clock is k GHz, the processor must do an encryption in k cycles to achieve this). This amazingly powerful attacker can test about 260 keys a second, so he needs 267 seconds against a 128-bit key. There are about 225 seconds in a year, so that is about 242 years. This is over 4,000,000,000,000 (four trillion) years so the cipher is clearly secure against brute force.

Many ciphers support larger keys as well; the reasons are discussed in the brute force attack article.

Principles and techniques

This section introduces the main principles of block cipher design, defines standard terms, and describes common techniques.

All of the principles and many of the terms and techniques discussed here for block ciphers also apply to other cryptographic primitives such as stream ciphers and cryptographic hash algorithms.

Iterated block ciphers

Nearly all block ciphers are iterated block ciphers; they have multiple rounds, each applying the same transformation to the output of the previous round. At setup time, a number of round keys or subkeys are computed from the primary key; the method used is called the cipher's key schedule. In the actual encryption or decryption, each round uses its own round key. This allows the designer to define some relatively simple transformation, called a round function, and apply it repeatedly to create a cipher with enough overall complexity to thwart attacks.

Any iterated cipher can be made more secure by increasing the number of rounds or made faster by reducing the number. In choosing the number of rounds, the cipher designer tries to strike a balance that achieves both security and efficiency simultaneously. Often a safety margin is applied; if the cipher appears to be secure after a certain number of rounds, the designer specifies a somewhat larger number for actual use.

There is a trade-off that can be made in the design. With a simple fast round function, many rounds may be required to achieve adequate security; for example, GOST and TEA both use 32 rounds. A more complex round function might allow fewer rounds; for example, IDEA uses only 8 rounds. Since the ciphers with fast round functions generally need more rounds and the ones with few rounds generally need slower round functions, neither strategy is clearly better. Secure and reasonably efficient ciphers can be designed either way, and compromises are common.

In cryptanalysis it is common to attack reduced round versions of a cipher. For example, in attacking a 16-round cipher, the analyst might start by trying to break a two-round or four-round version. Such attacks are much easier. Success against the reduced round version may lead to insights that are useful in work against the full cipher, or even to an attack that can be extended to break the full cipher.

Whitening and tweaking

Nearly all block ciphers use the same basic design, an iterated block cipher with multiple rounds. However, some have additional things outside that basic structure.

Whitening involves mixing additional material derived from the key into the plaintext before the first round, or into the ciphertext after the last round, or both. The technique was introduced by Ron Rivest in DES-X and has since been used in other ciphers such as RC6, Blowfish and Twofish. If the whitening material uses additional key bits, as in DES-X, then this greatly increases resistance to brute force attacks because of the larger key. If the whitening material is derived from the primary key during key scheduling, then resistance to brute force is not increased since the primary key remains the same size. However, using whitening is generally much cheaper than adding a round, and it does increase resistance to other attacks; see papers cited for DES-X.

A recent development is the tweakable block cipher
[1].
Where a normal block cipher has only two inputs, plaintext and key, a tweakable block cipher has a third input called the tweak. The tweak, along with the key, controls the operation of the cipher. Whitening can be seen as one form of tweaking, but many others are possible.

If changing tweaks is sufficiently lightweight, compared to the key scheduling operation which is often fairly expensive, then some new modes of operation become possible. Unlike the key, the tweak need not always be secret, though it should be somewhat random and in some applications it should change from block to block. Tweakable ciphers and the associated modes are an active area of current research.

The Hasty Pudding Cipher was one of the first tweakable ciphers, pre-dating the Tweakable Block Ciphers paper and referring to what would now be called the tweak as "spice".

Avalanche

The designer wants changes to quickly propagate through the cipher. This was named the avalanche effect in a paper [2] by Horst Feistel. The idea is that changes should build up like an avalanche, so that a tiny initial change (consider a snowball tossed onto a mountain) quickly creates large effects. The term and its exact application were new, but the basic concept was not; avalanche is a variant of Claude Shannon's diffusion, and that in turn is a formalisation of ideas that were already in use.

If a single bit of input or of the round key is changed at round <math>n</math>, that should affect all bits of the ciphertext by round <math>n+x</math> for some reasonably small <math>x</math>. Ideally, <math>x</math> would be 1, but this is not generally achieved in practice. Certainly <math>x</math> must be much less than the total number of rounds; if <math>x</math> is large, then the cipher will need more rounds to be secure.

The strict avalanche criterion[3] is a strong version of the requirement for good avalanche properties. Complementing any single bit of the input or the key should give exactly a 50% chance of a change in any given bit of output.

Cipher structures

In Claude Shannon's
[4]
terms, a cipher needs both confusion and diffusion, and a general design principle is that of the product cipher which combines several operations to achieve both goals. This goes back to the combination of substitution and transposition in various classical ciphers from before the advent of computers. All modern block ciphers are product ciphers.

Two structures are very commonly used in building block ciphers — SP networks and the Feistel structure. The Lai-Massey construction is a third alternative, less common than the other two. In Shannon's terms, all of these are product ciphers. Any of these structures is a known quantity for a cipher designer, part of the toolkit. He or she gets big chunks of a design — an overall cipher structure with a well-defined hole for the round function to fit into — from the structure, This leaves him or her free to concentrate on the hard part, designing the actual round function. None of these structures gives ideal avalanche in a single round but, with any reasonable round function, all give excellent avalanche after a few rounds.

Not all block ciphers use one of these structures, but most do. This section describes these common structures.

SP networks

A substitution-permutation network or SP network or SPN is Shannon's own design for a product cipher. It uses two layers in each round: a substitution layer provides confusion, then a permutation layer provides diffusion.

The S-layer typically uses look-up tables called substitution boxes or S-boxes, though other mechanisms are also possible. The input is XOR-ed with a round key, split into parts and each part used as an index into an S-box. The S-box output then replaces that part so the combined S-box outputs become the S-layer output. S-boxes are discussed in more detail in their own section below.

The P-layer permutes the resulting bits, providing diffusion or in Feistel's terms helping to ensure avalanche.

A single round of an SP network does not provide ideal avalanche; output bits are affected only by inputs to their S-box, not by all input bits. However, the P-layer ensures that the output of one S-box in one round will affect several S-boxes in the next round so, after a few rounds, overall avalanche properties can be very good.

Feistel structure

Another way to build an iterated block cipher is to use the Feistel structure. This technique was devised by Horst Feistel of IBM and used in DES. Such ciphers are known as Feistel ciphers or Feistel networks. In Shannon's terms, they are another class of product cipher.

Feistel ciphers are sometimes referred to as Luby-Rackoff ciphers after the authors of a theoretical paper
[5]
analyzing some of their properties. Later work
[6]
based on that shows that a Feistel cipher with seven rounds can be secure.

In a Feistel cipher, each round uses an operation called the F-function whose input is half a block and a round key; the output is a half-block of scrambled data which is XOR-ed into the other half-block of text. The rounds alternate direction — in one data from the left half-block is input and the right half-block is changed, and in the next round that is reversed.

Showing the half-blocks as left and right, bitwise XOR as <math>\oplus</math> (each bit of the output word is the XOR of the corresponding bits of the two input words) and round key for round <math>n</math> as kn, even numbered rounds are then:

Since XOR is its own inverse (a<math>\oplus</math>b<math>\oplus</math>b=a for any a,b) and the half-block that is used as input to the F-function is unchanged in each round, reversing a Feistel round is straightforward. Just calculate the F-function again with the same inputs and XOR the result into the ciphertext to cancel out the previous XOR. For example, the decryption step matching the first example above is:

In some ciphers, including those based on SP networks, all operations must be reversible so that decryption can work. The main advantage of a Feistel cipher over an SP network is that the F-function itself need not be reversible, only repeatable. This gives the designer extra flexibility; almost any operation he can think up can be used in the F-function. On the other hand, in the Feistel construction, only half the output changes in each round while an SP network changes all of it in a single round.

A single round in a Feistel cipher has less than ideal avalanche properties; only half the output is changed. However, the other half is changed in the next round so, with a good F-function, a Feistel cipher can have excellent overall avalanche properties within a few rounds. It is possible to design a Feistel cipher so that the F-function itself has ideal avalanche properties — every output bit depends nonlinearly on every input bit and every key bit — details are in a later section.

There is a variant called an unbalanced Feistel cipher in which the block is split into two unequal-sized pieces rather than two equal halves. Skipjack was a well-known example. There are also variations which treat the text as four blocks rather than just two; MARS and CAST-256 are examples.

The hard part of Feistel cipher design is of course the F-function. Design goals include efficiency, easy implementation, and good avalanche properties. Also, it is critically important that the F-function be highly nonlinear. All other operations in a Feistel cipher are linear and a cipher without enough nonlinearity is weak; see below.

One paper [9]
proposes a general class of "quasi-Feistel networks", with the Lai-Massey scheme as one instance, and shows that several of the well-known results on Feistel networks (such as the Luby-Rackoff and Patarin papers referenced above) can be generalised to the whole class. Another [10] gives some specific results for the Lai-Massey scheme.

Nonlinearity

To be secure, every cipher must contain nonlinear operations. If all operations in a cipher were linear then the cipher could be reduced to a system of linear equations and be broken by an algebraic attack. The attacker can choose which algebraic system to use; for example, against one cipher he might treat the text as a vector of bits and use Boolean algebra while for another he might choose to treat it as a vector of bytes and use arithmetic modulo 28. The attacker can also try linear cryptanalysis. If he can find a good enough linear approximation for the round function and has enough known plaintext/ciphertext pairs, then this will break the cipher. Defining "enough" in the two places where it occurs in the previous sentence is tricky; see linear cryptanalysis.

What makes these attacks impractical is a combination of the sheer size of the system of equations used (large block size, whitening, and more rounds all increase this) and nonlinearity in the relations involved. In any algebra, solving a system of linear equations is more-or-less straightforward provided there are more equations than variables. However, solving nonlinear systems of equations is far harder, so the cipher designer strives to introduce nonlinearity to the system, preferably to have at least some components that are not even close to linear. Combined with good avalanche properties and enough rounds, this makes both direct algebraic analysis and linear cryptanalysis prohibitively difficult.

There are several ways to add nonlinearity; some ciphers rely on only one while others use several.

One method is mixing operations from different algebras. If the cipher relies only on Boolean operations, the cryptanalyst can try to attack using Boolean algebra; if it uses only arithmetic operations, he can try normal algebra. If it uses both, he has a problem. Of course arithmetic operations can be expressed in Boolean algebra or vice versa, but the expressions are inconveniently (for the cryptanalyst!) complex and nonlinear whichever way he tries it.

For example, in the Blowfish F-function, it is necessary to combine four 32-bit words into one. This is not done with just addition, x = a+b+c+d or just Boolean operations x = a<math>\oplus</math>b<math>\oplus</math>c<math>\oplus</math>d but instead with a mixture, x = ((a+b)<math>\oplus</math>c)+d. On most computers this costs no more, but it makes the analyst's job harder.

Other operations can also be used, albeit at higher costs. IDEA uses multiplication modulo 216+1 and AES does matrix multiplications with polynomials in a Galois field.

Rotations, also called circular shifts, on words or registers are nonlinear in normal algebra, though they are easily described in Boolean algebra. GOST uses rotations by a constant amount, CAST-128 and CAST-256 use a key-dependent rotation in the F-function, and RC5, RC6 and MARS all use data-dependent rotations.

A general operation for introducing nonlinearity is the substitution box or S-box; see following section.

Nonlinearity is also an important consideration in the design of stream ciphers and cryptographic hash algorithms. For hashes, much of the mathematics and many of the techniques used are similar to those for block ciphers. For stream ciphers, rather different mathematics and methods apply (see Berlekamp-Massey algorithm for example), but the basic principle is the same.

S-boxes

S-boxes or substitution boxes are look-up tables. The basic operation involved is a = sbox[b] which, at least for reasonable sizes of a and b, is easily done on any computer.

S-boxes are described as <math>m</math> by <math>n</math>, with <math>m</math> representing the number of input bits and <math>n</math> the number of output bits. For example, DES uses 6 by 4 S-boxes. The storage requirement for an <math>m</math> by <math>n</math> S-box is 2mn bits, so large values of <math>m</math> (many input bits) are problematic. Values up to eight are common and MARS has a 9 by 32 S-box; going much beyond that would be expensive. Large values of <math>n</math> (many output bits) are not a problem; 32 is common and at least one system, the Tiger hash algorithm
[11],
uses 64.

S-boxes are often used in the S-layer of an SP Network. In this application, the S-box must have an inverse to be used in decryption. It must therefore have the same number of bits for input and output; only <math>n</math> by <math>n</math> S-boxes can be used. For example, AES is an SP network with a single 8 by 8 S-box and Serpent is one with eight 4 by 4 S-boxes. Another common application is in the F-function of a Feistel cipher. Since the F-function need not be reversible, there is no need to construct an inverse S-box for decryption and S-boxes of any size may be used.

With either an SP network or a Feistel construction, nonlinear S-boxes and enough rounds give a highly nonlinear cipher.

Large S-boxes

The first generation of Feistel ciphers used relatively small S-boxes, 6 by 4 for DES and 4 by 4 for GOST. In these ciphers the F-function is essentially one round of an SP Network. The eight S-boxes give 32 bits of S-box output. Those bits, reordered by a simple transformation, become the 32-bit output of the F-function. Avalanche properties are less than ideal since each output bit depends only on the inputs to one S-box. The output transformation (a bit permutation in DES, a rotation in GOST) compensates for this, ensuring that the output from one S-box in one round affects several S-boxes in the next round so that good avalanche is achieved after a few rounds.

Later Feistel ciphers use larger S-boxes; CAST-128 or CAST-256 and Blowfish all use four 8 by 32 S-boxes. They do not use S-box bits directly as F-function output. Instead, they take a 32-bit word from each S-box, then combine them to form a 32-bit output. This gives an F-function with ideal avalanche properties; every bit of input and every bit of round key affects every bit of output. No output transformation is required in such an F-function, and Blowfish has none. However, one may be used anyway; the CAST ciphers add a key-dependent rotation.

With the Feistel structure and such an F-function, complete avalanche — all 64 output bits depend on all 64 input bits — is achieved in three rounds, and the cipher meets the strict avalanche criterion[3]; complementing any input bit has a 50% chance of changing any given output bit.

These ciphers are primarily designed for software implementation, rather than the 1970s hardware DES was designed for, so looking up a full computer word at a time makes sense. An 8 by 32 S-box takes one K byte of storage; several can be used on a modern machine without difficulty. They need only four S-box lookups, rather than the eight in DES or GOST, so the F-function and therefore the whole cipher can be reasonably efficient.

S-box design

There is an extensive literature on the design of good S-boxes, much of it emphasizing achieving high nonlinearity though other criteria are also used. See external links.

The CAST S-boxes use bent functions (the most highly nonlinear Boolean functions) as their columns. That is, the mapping from all the input bits to any single output bit is a bent function. A paper on generating the S-boxes is Mister & Adams "Practical S-box Design"
[12].
Bent functions are combined to get additional desirable traits — a balanced S-box (equal probability of 0 and 1 output), minimum correlation among output bits, and high overall S-box nonlinearity.

Blowfish uses a different approach, generating random S-boxes as part of the key scheduling operation at cipher setup time. Such S-boxes are not as nonlinear as the carefully constructed CAST ones, but they are nonlinear enough and, unlike the CAST S-boxes, they are unknown to an attacker.

In perfectly nonlinear S-boxes[13],
not only are all columns bent functions (the most nonlinear possible Boolean functions), but all linear combinations of columns are bent functions as well. This is possible only if <math>m \ge 2n</math>, there are at least twice as many input bits as output bits. Such S-boxes are therefore not much used.

S-boxes in analysis

S-boxes are sometimes used as an analytic tool even for operations that are not actually implemented as S-boxes. Any operation whose output is fully determined by its inputs can be described by an S-box; concatenate all inputs into an index, look that index up, get the output. For example, the IDEA cipher uses a multiplication operation with two 16-bit inputs and one 16-bit output; it can be modeled as a 32 by 16 S-box. In an academic paper, one might use such a model in order to apply standard tools for measuring S-box nonlinearity. A well-funded cryptanalyst might actually build the S-box (8 gigabytes of memory) either to use in his analysis or to speed up an attack.

Resisting linear & differential attacks

Two very powerful cryptanalytic methods of attacking block ciphers are linear cryptanalysis and differential cryptanalysis. The former works by finding linear approximations for the nonlinear components of a cipher, then combining them using the piling-up lemma to attack the whole cipher. The latter looks at how small changes in the input affect the output, and how such changes propagate through multiple rounds. These are the only known attacks that break DES with less effort than brute force, and they are completely general attacks that apply to any block cipher..

Both these attacks, however, require large numbers of known or chosen plaintexts, so a simple defense against them is to re-key often enough that the enemy cannot collect sufficient texts.

Techniques introduced for CAST go further, building a cipher that is provably immune to linear or differential analysis with any number of texts. The method, taking linear cryptanalysis as our example and abbreviating it LC, is as follows:

start from properties of the round function (for CAST, from bent functions in the S-boxes)

derive a limit <math>m</math>, the maximum possible quality of any linear approximation to a single round

consider the number of rounds, <math>r</math>, as a variable

derive an expression for <math>e</math>, the effort required to break the cipher by LC, in terms of <math>r</math> and <math>m</math>

find the minimum <math>r</math> such that <math>e</math> exceeds the effort required for brute force, making LC impractical

derive an expression for <math>c</math>, the number of chosen plaintexts required for LC, also in terms of <math>r</math> and <math>m</math> (LC with only known plaintext requires more texts, so it can be ignored)

find the minimum <math>r</math> such that <math>c</math> exceeds the number of possible plaintexts, 2blocksize, making LC impossible

A similar approach applied to differentials gives values for <math>r</math> that make differential cryptanalysis impractical or impossible. Choose the actual number of rounds so that, at a minimum, both attacks are impractical. Ideally, make both impossible, then add a safety factor. There are other methods of constructing ciphers provably immune to these attacks. Serge Vaudenay's work on decorrelation theory gives one [14]
and Knudsen-Nyberg ciphers are another. [15]

This type of analysis is now a standard part of the cryptographer's toolkit. Many of the AES candidates, for example, included proofs along these lines in their design documentation, and AES itself uses such a calculation to determine the number of rounds required for various key sizes.

DES and alternatives

The Data Encryption Standard, DES, is among the best known and most thoroughly analysed block ciphers. It was invented by IBM and was made a US government standard, for non-classified government data and for regulated industries such as banking, in the late 70s. From then until about the turn of the century, it was very widely used. It is now considered obsolete because its 56-bit key is too short to resist brute force attacks if the opponents have recent technology.

The DES standard marked the beginning of an era in cryptography. Of course, much work continued to be done in secret by military and intelligence organisations of various nations, but from the time of DES cryptography also developed as an open academic discipline complete with journals, conferences, courses and textbooks. In particular, there was a lot of work related to block ciphers. For an entire generation, every student of cryptanalysis tried to find a way to break DES and every student of cryptography tried to devise a cipher that was demonstrably better than DES. Very few succeeded.

Every new cryptanalytic technique invented since DES became a standard has been tested against DES. None of them have broken it completely, but two — differential cryptanalysis and linear cryptanalysis — give attacks theoretically significantly better than brute force. This does not appear to have much practical importance since both require enormous numbers of known or chosen plaintexts, all encrypted with the same key, so reasonably frequent key changes provide an effective defense. All the older publicly known cryptanalytic techniques have also been tried, or at least considered, for use against DES; none of them work.

DES served as a sort of baseline for cipher design through the 80s and 90s; the design goal for almost any 20th century block cipher was to replace DES in some of its many applications with something faster, more secure, or both. All these ciphers used 64-bit blocks, like DES, but most used 128-bit or longer keys for better resistance to brute force attacks.

SAFER and LOKI, two families of ciphers which each included an original version against which Lars Knudsen found an attack and a revised version to block that attack. Each had a descendant which was an AES candidate.

Many of the techniques used in these ciphers came from DES and many of the design principles came from analysis of DES. However, there were also new design ideas. The CAST ciphers were the first to use large S-boxes which allow the F-function of a Feistel cipher to have ideal avalanche properties, and to use bent functions in the S-box columns. Blowfish introduced key-dependent S-boxes. Several introduced new ways to achieve nonlinearity: data-dependent rotations in RC5, key-dependent rotations in CAST-128, a clever variant on multiplication in IDEA, and the pseudo-Hadamard transform in SAFER.

The era effectively ended when the US government began working on a new cipher standard to replace their Data Encryption Standard, the Advanced Encryption Standard or AES. A whole new generation of ciphers arose, the first 21st century block ciphers. Of course these designs still drew on the experience gained in the post-DES generation, but overall these ciphers are quite different. In particular, they all use 128-bit blocks and most support key sizes up to 256 bits.

To do this, they ran a very open international AES competition, starting in 1998. Their requirements specified a block cipher with 128-bit block size and support for 128, 192 or 256-bit key sizes. Evaluation criteria included security, performance on a range of platforms from 8-bit CPUs (e.g. in smart cards) up, and ease of implementation in both software and hardware.

An entire generation of block ciphers used the 64-bit block size of DES, but since AES many new designs use a 128-bit block size.

As discussed under size parameters, if two or more ciphers have the same block and key sizes, then they are effectively interchangeable; replacing one cipher with another requires no other changes in an application. When asked to implement AES, the implementer might include the other finalists — Twofish, Serpent. RC6 and MARS — as well. This provides useful insurance against the (presumably unlikely) risk of someone finding a good attack on AES. Little extra effort is required since open source implementations of all these ciphers are readily available, see external links. All except RC6 have completely open licenses.

There are also many other ciphers that might be used. There were ten AES candidates that did not make it into the finals:

Large-block ciphers

For most applications a 64-bit or 128-bit block size is a fine choice; nearly all common block ciphers use one or the other. Such ciphers can be used to encrypt objects larger than their block size; just choose an appropriate mode of operation.

For nearly all ciphers, the block size is a power of two. Joan Daemen's PhD thesis, though, had two exceptions: 3-Way uses 96 bits (three 32-bit words) and BaseKing 192 (three 64-bit words). Neither cipher was widely used, but they did influence later designs. Daemen was one of the designers of Square and of Rijndael which became the Advanced Encryption Standard.

A few ciphers supporting larger block sizes do exist; this section discusses them.

A block cipher with larger blocks may be more efficient; it takes fewer block operations to encrypt a given amount of data. It may also be more secure in some ways; diffusion takes place across a larger block size, so data is more thoroughly mixed, and large blocks make a code book attack more difficult. On the other hand, great care must be taken to ensure adequate diffusion within a block so a large-block cipher may need more rounds, larger blocks require more padding, and there is not a great deal of literature on designing and attacking such ciphers so it is hard to know if one is secure. Large-block ciphers are inconvenient for some applications and simply do not fit in some protocols.

Some block ciphers, such as Block TEA and Hasty Pudding, support variable block sizes. They may therefore be both efficient and convenient in applications that need to encrypt many items of a fixed size, for example disk blocks or database records. However, just using the cipher in ECB mode to encrypt each block under the same key is unwise, especially if encrypting many objects. With ECB mode, identical blocks will encrypt to the same ciphertext and give the enemy some information. One solution is to use a tweakable cipher such as Hasty Pudding with the block number or other object identifier as the tweak. Another is to use CBC mode with an initialisation vector derived from an object identifier.

Cryptographic hash algorithms can be built using a block cipher as a component. There are general-purpose methods for this that can use existing block ciphers; Applied Cryptography[16]
gives a long list and describes weaknesses in many of them. However, some hashes include a specific-purpose block cipher as part of the hash design. One example is Whirlpool, a 512-bit hash using a block cipher similar in design to AES but with 512-bit blocks and a 512-bit key. Another is the Advanced Hash Standard candidate Skein which uses a tweakable block cipher called Threefish. Threefish has 256-bit, 512-bit and 1024-bit versions; in each version block size and key size are both that number of bits.

It is possible to go the other way and use any cryptographic hash to build a block cipher; again Applied Cryptography[16] has a list of techniques and describes weaknesses. The simplest method is to make a Feistel cipher with double the hash's block size; the F-function is then just to hash text and round key together. This technique is rarely used, partly because a hash makes a rather expensive round function and partly because the block cipher block size would have to be inconveniently large; for example using a 160-bit bit hash such as SHA-1 would give a 320-bit block cipher.

The hash-to-cipher technique was, however, important in one legal proceeding, the Bernstein case. At the time, US law strictly controlled export of cryptography because of its possible military uses, but hash functions were allowed because they are designed to provide authentication rather than secrecy. Bernstein's code built a block cipher from a hash, effectively circumventing those regulations. Moreover, he sued the government over his right to publish his work, claiming the export regulations were an unconstitutional restriction on freedom of speech. The courts agreed, effectively striking down the export controls.

It is also possible to use a public key operation as a block cipher. For example, one might use the RSA algorithm with 1024-bit keys as a block cipher with 1024-bit blocks. Since the round function is itself cryptographically secure, only one round is needed. However, this is rarely done; public key techniques are expensive so this would give a very slow block cipher. A much more common practice is to use public key methods, block ciphers, and cryptographic hashes together in a hybrid cryptosystem.